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Reviews of topical problems


On the nonequilibrium diagram technique: derivation, some features and applications


Lebedev Physical Institute, Russian Academy of Sciences, Leninsky prosp. 53, Moscow, 119991, Russian Federation

The logic of the nonequilibrium diagram technique (Keldysh diagram technique) appearance is reviewed. Simple examples are used to illustrate the implementation of the technique and to demonstrate possible difficulties and how to overcome them. Together with the well known facts, some lesser-discussed details are considered, in particular, whether the so-called three-component technique is necessary. A number of examples of nonequilibrium diagram technique (NDT) applications are given, including in particular tunneling systems, the linear response and other problems. We hope that some parts of the review will be useful even for those people for whom nonequilibrium diagram technique is well familiar.

Fulltext pdf (1.1 MB)
Fulltext is also available at DOI: 10.3367/UFNe.0185.201512b.1271
Keywords: diagram technique, nonequilibrium diagram technique, Keldysh diagram technique, nonequilibrium processes, quantum kinetics
PACS: 03.70.+k, 05.60.Gg, 11.10.Wx, 72.10.Bg (all)
DOI: 10.3367/UFNe.0185.201512b.1271
URL: https://ufn.ru/en/articles/2015/12/b/
000371914300002
2-s2.0-84962798469
2015PhyU...58.1159A
Citation: Arseev P I "On the nonequilibrium diagram technique: derivation, some features and applications" Phys. Usp. 58 1159–1205 (2015)
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Received: 4th, August 2015, revised: 11th, October 2015, 12th, October 2015

Îðèãèíàë: Àðñååâ Ï È «Î äèàãðàììíîé òåõíèêå äëÿ íåðàâíîâåñíûõ ñèñòåì: âûâîä, íåêîòîðûå îñîáåííîñòè è íåêîòîðûå ïðèìåíåíèÿ» ÓÔÍ 185 1271–1321 (2015); DOI: 10.3367/UFNr.0185.201512b.1271

References (114) Cited by (52) ↓ Similar articles (20)

  1. Yu K M, I K K et al Springer Series In Solid-State Sciences Vol. Electronic Phase Separation in Magnetic and Superconducting MaterialsInhomogeneous Fermi–Bose Mixture in the Aharonov–Bohm Ring with Topologically Nontrivial Superconducting Bridge201 Chapter 15 (2024) p. 317
  2. Aksenov S V Pisʹma V žurnal êksperimentalʹnoj I Teoretičeskoj Fiziki 120 51 (2024)
  3. Aksenov S V, Kagan M Yu J Low Temp Phys 217 145 (2024)
  4. Popov F K Phys. Rev. D 110 (12) (2024)
  5. Nguyen D-P, Arwas G, Ciuti C Phys. Rev. B 110 (19) (2024)
  6. Yu K M, I K K et al Springer Series In Solid-State Sciences Vol. Electronic Phase Separation in Magnetic and Superconducting MaterialsManifestation of the EPE in the Microcontact with Deep and Shallow Traps201 Chapter 11 (2024) p. 231
  7. Aksenov S V Jetp Lett. 120 56 (2024)
  8. Mantsevich V N, Smirnov D S Phys. Rev. B 110 (3) (2024)
  9. Radovskaya A A, Semenov A G Jetp Lett. 118 922 (2023)
  10. Klyuchantsev A B, Dzebisashvili D M Phys. Scr. 98 035811 (2023)
  11. Mantsevich V N, Smirnov D S Phys. Rev. B 108 (3) (2023)
  12. Trunin D A Phys. Rev. D 107 (6) (2023)
  13. Kolganov N J. High Energ. Phys. 2023 (10) (2023)
  14. Yang Ya, Zhang L et al Phys. Chem. Chem. Phys. 25 16363 (2023)
  15. Trunin D A Phys. Rev. D 108 (10) (2023)
  16. Radovskaya A A, Semenov A G Pisʹma V žurnal êksperimentalʹnoj I Teoretičeskoj Fiziki 118 921 (2023)
  17. Idrisov E G, Hasdeo E H et al 49 1385 (2023)
  18. Kopchinskii I D, Shorokhov V V Russ Microelectron 52 S337 (2023)
  19. Maslova N S, Arseyev P I et al Physica E: Low-dimensional Systems And Nanostructures 146 115553 (2023)
  20. Melo J F SciPost Phys. Core 6 (1) (2023)
  21. Trunin D A Eur. Phys. J. C 82 (5) (2022)
  22. Vyshnevyy A A Phys. Rev. B 105 (8) (2022)
  23. Mylnikov V Yu, Potashin S O et al Nanomaterials 12 2543 (2022)
  24. Krivopol V A, Nalimov M Yu Theor Math Phys 213 1774 (2022)
  25. Kolganov N, Trunin D A Phys. Rev. D 106 (2) (2022)
  26. Mantsevich V N, Smirnov D S Nanoscale Horiz. 7 752 (2022)
  27. Moulhim A, Tripathi B, Kumar M Micro And Nanostructures 168 207284 (2022)
  28. Val’kov V V, Shustin M S et al Phys.-Usp. 65 2 (2022)
  29. Glazov M M, Golub L E Phys. Rev. B 106 (23) (2022)
  30. Trunin D A Phys.-Usp. 64 219 (2021)
  31. Moulhim A, Tripathi B et al Superlattices And Microstructures 151 106819 (2021)
  32. Trunin D A Phys. Rev. D 104 (4) (2021)
  33. Maslova N S, Arseyev P I, Mantsevich V N Sci Rep 11 (1) (2021)
  34. Rozhansky I V, Mantsevich V N et al Physica E: Low-dimensional Systems And Nanostructures 132 114755 (2021)
  35. Maslova N S, Mantsevich V N et al Sci Rep 11 (1) (2021)
  36. Shchurova L Yu, Murzin V N J Russ Laser Res 42 632 (2021)
  37. Rozhansky I V, Mantsevich V N et al Phys. Rev. B 101 (4) (2020)
  38. Anikin E V, Maslova N S et al Phys. Rev. A 102 (3) (2020)
  39. Aksenov S V, Kagan M Yu Jetp Lett. 111 286 (2020)
  40. Altshuler B L Int. J. Mod. Phys. A 35 2050001 (2020)
  41. Akhmedov E T, Diatlyk O N, Semenov A G Proc. Steklov Inst. Math. 309 12 (2020)
  42. Akhmedov Emil Tofik ogly, Diatlyk O, Semenov A G Trudy Matematicheskogo Instituta Imeni V. A. Steklova 309 18 (2020)
  43. Guerci D Phys. Rev. B 99 (19) (2019)
  44. Maslova N S, Arseyev P I, Mantsevich V N Sci Rep 9 (1) (2019)
  45. Gorbatsevich A A, Shubin N M Jetp Lett. 110 618 (2019)
  46. Val’kov V V, Aksenov S V 45 165 (2019)
  47. Idrisov E G, Schmidt T L Phys. Rev. B 100 (16) (2019)
  48. Val’kov V V, Aksenov S V Theor Math Phys 194 236 (2018)
  49. Pogorelov Yu G, Loktev V M 44 1 (2018)
  50. Mantsevich V N, Glazov M M Phys. Rev. B 97 (15) (2018)
  51. Enaldiev V V Phys. Rev. B 96 (23) (2017)
  52. Arseev P I, Mantsevich V N et al Uspekhi Fizicheskikh Nauk 187 1147 (2017) [Arseev P I, Mantsevich V N et al Phys.-Usp. 60 1067 (2017)]

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